CROSS-REFERENCE TO RELATED APPLICATIONSThis application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/502,559 filed on Jun. 29, 2011, and entitled “System and Method For Controlling Focused Ultrasound Treatment.”
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCHThis invention was made with government support under EB003268 and EB000705 awarded by the National Institutes of Health. The government has certain rights in the invention.
BACKGROUND OF THE INVENTIONThe field of the invention is systems and methods for focused ultrasound. More particularly, the invention relates to systems and methods for controlling the delivery of focused ultrasound.
Focused ultrasound (“FUS”) disruption of the blood-brain barrier (“BBB”) using circulating microbubbles is a field of increasing research with the potential to revolutionize treatment of brain and central nervous system (“CNS”) disorders. The BBB prevents passage of molecules from the vasculature into the brain tissue when the molecules are larger than around five hundred Daltons, thereby significantly reducing the efficacy of pharmaceutical and other agents.
FUS disruption of the BBB has been successfully used to deliver amyloid-beta antibodies, as described by J. F. Jordao, et al., in “Antibodies Targeted to the Brain with Image-Guided Focused Ultrasound Reduces Amyloid-Beta Plaque Load in the TgCRND8 Mouse Model of Alzheimer's Disease,” PLoS One 2010; 5:e10549; large molecule chemotherapy agents, as described by M. Kinoshita, et al., in “Noninvasive Localized Delivery of Herceptin to the Mouse Brain by MRI-Guided Focused Ultrasound-Induced Blood-Brain Barrier Disruption,” Proc. Natl. Acad. Sci. USA, 2006; 103:11719-11723; and other large molecules of clinically relevant size, as described by J. J. Choi, et al., in “Molecules of Various Pharmacologically-Relevant Sizes Can Cross the Ultrasound-Induced Blood-Brain Barrier Opening In Vivo,” Ultrasound Med. Biol., 2010; 36:58-67.
Currently, the greatest limitation for the clinical translation of FUS BBB disruption (“BBBD”) is the lack of a real-time technique for monitoring the delivery of FUS to the subject. Disruption can be evaluated using contrast-enhanced magnetic resonance imaging (“MRI”), but such methods provide insufficient temporal resolution to provide real-time feedback.
The introduction of ultrasound contrast agents, such as microbubble contrast agents, to the brain can be seen as a safety concern, especially when using transcranial FUS. Moreover, the use of ultrasound in the skull cavity has been known to make estimation of in situ pressure magnitudes and distributions more difficult, as described by M. A. O'Reilly, et al., in “The Impact of Standing Wave Effects on Transcranial Focused Ultrasound Disruption of the Blood-Brain Barrier in a Rat Model,” Phys. Med. Biol., 2010; 55:5251-5267. This increased difficulty in pressure estimation when using transcranial ultrasound highlights the need for a real-time technique to monitor the microbubble behavior during FUS induced BBBD.
Studies have been conducted to examine the effects of various acoustic and contrast agent parameters on BBBD in an attempt to identify optimal disruption parameters. For example, see the studies described by F.-Y. Yang, et al., in Quantitative Evaluation of the Use of Microbubbles with Transcranial Focused Ultrasound on Blood-Brain-Barrier Disruption,”Ultrason. Sonochem.,2008; 15:636-643; by N. McDannold, et al., in “Effects of Acoustic Parameters and Ultrasound Contrast Agent Dose on Focused-Ultrasound Induced Blood-Brain Barrier Disruption,”Ultrasound Med. Biol.,2008; 34:930-937; by R. Chopra, et al., in “Influence of Exposure Time and Pressure Amplitude on Blood-Brain-Barrier Opening using Transcranial Ultrasound Exposures,”ACS Chem. Neurosci.,2010; 1:391-398; and by J. J. Choi, et al., in “Microbubble-Size Dependence of Focused Ultrasound-Induced Blood-Brain Barrier Opening in Mice In Vivo,”IEEE Trans. Biomed. Eng.,2010; 57:145-154.
Other studies have preferred to examine the microbubble emissions during BBBD in order to identify an emissions characteristic that could identify an appropriate treatment endpoint. For example, a sharp increase in harmonic emissions during sonications resulting in successful BBBD has been observed, as described by N. McDannold, et al., in “Targeted Disruption of the Blood-Brain Barrier with Focused Ultrasound: Association with Cavitation Activity,”Phys. Med. Biol.,2006; 51:793-807. In another study, the presence of the fourth and fifth harmonics where observed when BBBD occurred, as described by Y.-S. Tung, et al., in “In Vivo Transcranial Cavitation Threshold Detection During Ultrasound-Induced Blood-Brain Barrier Opening in Mice,” Phys. Med. Biol., 2010; 55:6141-6155. It was observed that these higher harmonics were absent when BBBD was unsuccessful; however, harmonic signal content can arise from the tissue or coupling media, and not just the circulating microbubbles. As a result, these harmonic signal components may not result in the most robust method of controlling treatments.
It would therefore be desirable to provide a system and method for controlling the delivery of ultrasound energy to a subject such that blood-brain barrier disruption can be achieved without injury to the subject.
SUMMARY OF THE INVENTIONA system and method for controlling the delivery of ultrasound energy to a subject is provided. In particular, such a system and method are capable of safely disrupting the blood-brain barrier. Ultrasound energy is delivered to produce cavitation of an ultrasound contrast agent at a selected pressure value. An acoustic signal is acquired following cavitation, from which a signal spectrum is produced. The signal spectrum is analyzed for the presence of harmonics, such as subharmonics or ultraharmonics. When subharmonics or ultraharmonics are present, the pressure value is decreased for subsequent sonications. If a previous sonication resulted in no subharmonics or ultraharmonics being generated, then the pressure value may be increased. In this manner, the blood-brain barrier can be advantageously disrupted while mitigating potentially injurious effects of the sonication.
The foregoing and other aspects and advantages of the invention will appear from the following description. In the description, reference is made to the accompanying drawings which form a part hereof, and in which there is shown by way of illustration a preferred embodiment of the invention. Such embodiment does not necessarily represent the full scope of the invention, however, and reference is made therefore to the claims and herein for interpreting the scope of the invention.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 is a block diagram of an exemplary focused ultrasound (“FUS”) system that can be employed when practicing some embodiments of the present invention;
FIG. 2 is a block diagram of another exemplary FUS system that can be employed when practicing some embodiments of the present invention;
FIG. 3 is a flowchart setting forth the steps of an exemplary method for controlling sonications produced by an FUS system such that blood-brain barrier disruption can be achieved without injury to a subject; and
FIG. 4 is a block diagram of an exemplary magnetic resonance guided focused ultrasound (“MRgFUS”) system that is employed when practicing some embodiments of the present invention.
DETAILED DESCRIPTION OF THE INVENTIONA system and method for controlling the delivery of ultrasound energy to a subject with a focused ultrasound (“FUS”) system is provided. Particularly, ultrasound energy is delivered to the subject in a controlled manner such that blood-brain barrier disruption can be achieved without injury to the subject. The presence of subharmonics or ultraharmonics in the spectral profile of acoustic signals acquired following the delivery of ultrasound energy to the subject is utilized to adjust parameters of subsequent sonications, such as acoustic pressure. Preferably, microbubble contrast agents are used and the emissions from these microbubbles during sonication are spectrally analyzed in real-time to guide subsequent sonications. The provided system and method may also be utilized to perform acoustically controlled non-thermal lesioning using circulating microbubbles for treating tumors in near-skull regions where thermal ablation is unachievable. Since the blood-brain barrier is also disrupted in the focal region during treatment, a therapy agent can also be delivered after initial lesioning in order to improve treatment efficacy.
Referring toFIG. 1, an exemplary focused ultrasound (“FUS”)system100 for delivering focused ultrasound to a subject102 is illustrated. The FUS system includes acontroller104, anultrasound transducer106, anenclosure108, and apositioning system110. Theenclosure108 houses theultrasound transducer106 and provides an interface with the subject102 such that ultrasound energy can be efficiently transferred from theultrasound transducer106 to the subject102. By way of example, theenclosure108 is filled with anacoustic coupling medium112, which allows for a more efficient propagation of ultrasound energy than through air. Exemplaryacoustic coupling media112 include water, such as degassed water. Advantageously, theultrasound transducer106 includes asignal detector114, such as a hydrophone. By way of example, thesignal detector114 may include a wideband polyvinylidene fluoride (“PVDF”) hydrophone, such as those described by M. A. O'Reilly and K. Hynynen in “A PVDF Receiver for Ultrasound Monitoring of Transcranial Focused Ultrasound Therapy,” IEEE Transactions on Biomedical Engineering, 2010; 57(9):2286-2294. Theultrasound transducer106 is coupled to thepositioning system110 by way of asupport116. Thepositioning system110 is advantageously a three-axis positioning system that provides precise and accurate positioning of theultrasound transducer106 in three dimensions.
Thecontroller104 generally includes aprocessor118, asignal generator120, and a radio frequency (“RF”)amplifier122. Thesignal generator120 may include, for example, a function generator, and is configured to provide a driving signal that directs theultrasound transducer106 to generate ultrasound energy. The driving signal produced by thesignal generator120 is amplified by theRF amplifier122 before being received by theultrasound transducer106. Theultrasound transducer106 may also be a phased array transducer. When theFUS system100 is used during a magnetic resonance guided FUS (“MRgFUS”) application, thecontroller104 can be positioned inside or outside of the magnet room of the magnetic resonance imaging (“MRI”) system.
Theprocessor118 is in communication with thesignal generator120 and directs thesignal generator120 to produce the driving signal that is delivered to theultrasound transducer106. As will be described below in detail, theprocessor118 may be configured to adjust properties of the driving signal such that the ultrasound energy pressure produced by theultrasound transducer106 is adjusted in accordance with embodiments of the present invention.
Theprocessor118 receives acoustic signals from thesignal detector114. As will be described below in detail, the feedback information provided by thesignal detector114 is utilized by theprocessor118 to direct the appropriate adjustments in ultrasound energy. Theprocessor118 is also in communication with thepositioning system110, and is configured to direct thepositioning system110 to move the position of theultrasound transducer106 during a sonication procedure. In the case that theultrasound transducer106 is a phased array transducer, thecontroller104 may adjust the phase and/or amplitude of the driving RF signal to each transducer element to control the location of the focal spot.
Theultrasound transducer106 is preferably a spherically-focused transducer matched to a desired frequency using an external matching circuit. In some configurations, theultrasound transducer106 is designed so that thesignal detector114 may be mounted in the center of theultrasound transducer106.
Referring now toFIG. 2, in some instances, anFUS system200 may be configured more particularly for transcranial ultrasound applications in human subjects. In such a system, a subject202 receives ultrasound energy from atransducer206 that is configured to surround an extent of the subject's head. For example, thetransducer206 may be a hemispherical array of transducer elements. TheFUS system200 may include a cooling system, such as a sealed water system with an active cooling and degassing capacity, so that an appropriate and comfortable temperature of the skull and skin of the subject202 may be maintained during treatment.
TheFUS system200 includes aprocessor218 that is in communication with amulti-channel amplifier224 and amulti-channel receiver226. Themulti-channel amplifier224 received driving signals from theprocessor218 and, in turn, directs the transducer elements of thetransducer206 to generate ultrasound energy. Themulti-channel receiver226 receives acoustic signals during sonications and relays these signals to theprocessor218 for processing in accordance with embodiments of the present invention. Theprocessor218 may also be configured to adjust the driving signals in response to the acoustic signals received by themulti-channel receiver226. For example, the phase and/or amplitude of the driving signals may be adjusted so that ultrasound energy is more efficiently transmitted through the skull of the subject202 and into the target volume-of-interest230. Furthermore, the acoustic signals may also be analyzed to determine whether and how the extent of the focal region should be adjusted. As will be described below in detail, magnetic resonance imaging (“MRI”) may also be used to guide the application of ultrasound energy to the subject202. Thus, an MRI system, generally indicated as dashedbox232, may be used to acquiredMRI images234 of the subject202. TheMRI images234 may then be provided to theprocessor218 to adjust the parameters of the sonications. For example, the phase and/or amplitude of the driving signals may be adjusted so that ultrasound energy is more efficiently transmitted through the skull of the subject202 and into the target volume-of-interest230. It is noted that other imaging modalities, such as computed tomography (“CT”), positron emission tomography (“PET”), single-photon emission computed tomography (“SPECT”), and ultrasound may also be used to guide the treatment.
Referring now toFIG. 3, a flowchart setting forth the steps of an exemplary method for controlling a focused ultrasound (“FUS”) system is illustrated. This method for controlling an FUS system provides for the delivery of ultrasound energy to a subject so that an advantageous disruption of the blood-brain barrier is achieved without injury to the subject. First, a contrast agent is administered to the subject, as illustrated atstep302. Exemplary contrast agents include microbubble ultrasound contrast agents, such as those marketed under the name Definity® (Lantheus Medical Imaging; North Billerica, Mass.). As the contrast agent is circulating through the subject, ultrasound energy is delivered to a target volume using a focused ultrasound (“FUS”) system, as indicated atstep304. The ultrasound energy is delivered with delivery parameters, such as acoustic power, that are selected so as to produce a desired pressure in the target volume. By way of example, the delivery of ultrasound energy, or “sonication,” may be performed using continuous wave bursts having a fundamental frequency of 551.5 kHz. Acoustic signal data is acquired following the delivery of the ultrasound energy, as indicated atstep306. This signal data is then processed to determine whether the ultrasound energy delivered in the next delivery should be adjusted.
The acquired acoustic signal is first transformed into frequency space to produce a signal spectrum, as indicated atstep308. For example, a fast Fourier transform is applied to the acoustic signal to produce the signal spectrum. The produced signal spectrum is then analyzed, as indicated atstep310. By way of example, the signal spectrum is integrated over to identify the presence of harmonics in the signal spectrum. More particularly, the signal spectrum may be analyzed to identify the presence of subharmonics or ultraharmonics of the fundamental frequency, f0, of the ultrasound energy, such as 0.5f0, 1.5f0, and 2.5f0. By integrating over the signal spectrum around the frequency values for these subharmonics or ultraharmonics, and comparing the results with the respective spectral values for a signal spectrum acquired before the contrast agent was administered to the subject, the presence of the subharmonics or ultraharmonics can be evaluated.
After analyzing the signal spectrum, a determination is made whether one or more subharmonics or ultraharmonics are present in the signal spectrum, as indicated atdecision block312. If one or more subharmonics or ultraharmonics are identified in the signal spectrum, then the pressure of the ultrasound energy is decreased before the next delivery, as indicated atstep314. For example, the pressure may be decreased in accordance with:
Pi+1=γ·Pi (1);
where Piis the pressure used for the ithsonication, Pi+1is the pressure that will be used for the (i+1)thsonication, and γ is a factor that decreases the pressure to a target level as a normalized value of pressure for subharmonic or ultraharmonic emissions. An exemplary target level of ultrasound energy pressure includes a user selected percentage of the pressure required to induce detectable levels of subharmonic or ultraharmonic emissions.
After this adjustment, the next ultrasound delivery is performed, and steps304-312 may be repeated if more ultrasound energy is to be delivered to the subject. If no subharmonics or ultraharmonics are present in the signal spectrum then a determination is made atdecision block316 whether subharmonics or ultraharmonics were present in signal spectra from previous ultrasound energy deliveries. For example, if the first sonication results in a signal spectrum with no ultraharmonics, then this information is stored and, following the second sonication, the determination atdecision block316 would be that no ultraharmonics were present in the previous signal spectrum. If no ultraharmonics were identified in the previous signal spectrum, then it may be appropriate to increase the ultrasound energy pressure for the next sonication. Thus, as indicated atstep318, the pressure can be increased. For example, the pressure may be increased in accordance with:
Pi+1=Pi+δP (2);
where δP is an incremental pressure value. If subharmonics or ultraharmonics were identified in the previous signal spectrum, then the pressure is maintained at its current level, or reduced depending on the level of tissue damage that is desired. If blood-brain barrier disruption is desired without other effects on tissue, then the pressure level may be reduced for the subsequent sonications. If more sonications are desired, then the process loops back to perform steps304-318, as indicated at decision block320.
Thus, a system and method for actively controlling blood-brain barrier disruption using acoustic emissions monitoring has been provided. Using the provided system and method, it is contemplated that the blood-brain barrier can be safely disrupted without knowledge of in situ pressures.
The aforementioned FUS treatment can be further monitored and guided with the aid of magnetic resonance imaging (“MRI”). To this end, a magnetic resonance guided focused ultrasound (“MRgFUS”) system may be utilized. Referring particularly now toFIG. 4, an exemplary MRgFUS system400 is illustrated. The MRgFUS system400 includes aworkstation402 having adisplay404 and akeyboard406. Theworkstation402 includes aprocessor408, such as a commercially available programmable machine running a commercially available operating system. Theworkstation402 provides the operator interface that enables scan prescriptions to be entered into the MRgFUS system400. Theworkstation402 is coupled to four servers: apulse sequence server410; adata acquisition server412; adata processing server414, and adata store server416. Theworkstation402 and eachserver410,412,414 and416 are connected to communicate with each other.
Thepulse sequence server410 functions in response to instructions downloaded from theworkstation402 to operate agradient system418 and a radiofrequency (“RF”)system420. Gradient waveforms necessary to perform the prescribed scan are produced and applied to thegradient system418, which excites gradient coils in anassembly422 to produce the magnetic field gradients Gx, Gy, and Gzused for position encoding MR signals. Thegradient coil assembly422 forms part of amagnet assembly424 that includes apolarizing magnet426 and a whole-body RF coil428.
RF excitation waveforms are applied to theRF coil428, or a separate local coil (not shown inFIG. 4), by theRF system420 to perform the prescribed magnetic resonance pulse sequence. Responsive MR signals detected by theRF coil428, or a separate local coil (not shown inFIG. 4), are received by theRF system420, amplified, demodulated, filtered, and digitized under direction of commands produced by thepulse sequence server410. TheRF system420 includes an RF transmitter for producing a wide variety of RF pulses used in MR pulse sequences. The RF transmitter is responsive to the scan prescription and direction from thepulse sequence server410 to produce RF pulses of the desired frequency, phase, and pulse amplitude waveform. The generated RF pulses may be applied to the wholebody RF coil428 or to one or more local coils or coil arrays (not shown inFIG. 4).
TheRF system420 also includes one or more RF receiver channels. Each RF receiver channel includes an RF amplifier that amplifies the MR signal received by thecoil428 to which it is connected, and a detector that detects and digitizes the I and Q quadrature components of the received MR signal. The magnitude of the received MR signal may thus be determined at any sampled point by the square root of the sum of the squares of the I and Q components:
M=√{square root over (I2+Q2)} (3);
and the phase of the received MR signal may also be determined:
Thepulse sequence server410 also optionally receives patient data from aphysiological acquisition controller430. Thecontroller430 receives signals from a number of different sensors connected to the patient, such as electrocardiograph (“ECG”) signals from electrodes, or respiratory signals from a bellows or other respiratory monitoring device. Such signals are typically used by thepulse sequence server410 to synchronize, or “gate,” the performance of the scan with the subject's heart beat or respiration.
Thepulse sequence server410 also connects to a scanroom interface circuit432 that receives signals from various sensors associated with the condition of the patient and the magnet system. It is also through the scanroom interface circuit432 that apatient positioning system434 receives commands to move the patient to desired positions during the scan.
The digitized MR signal samples produced by theRF system420 are received by thedata acquisition server412. Thedata acquisition server412 operates in response to instructions downloaded from theworkstation402 to receive the real-time MR data and provide buffer storage, such that no data is lost by data overrun. In some scans, thedata acquisition server412 does little more than pass the acquired MR data to thedata processor server414. However, in scans that require information derived from acquired MR data to control the further performance of the scan, thedata acquisition server412 is programmed to produce such information and convey it to thepulse sequence server410. For example, thedata acquisition server412 may acquire MR data and processes it in real-time to produce information that may be used to control the acquisition of MR data, or to control the sonications produced by the FUS system.
Thedata processing server414 receives MR data from thedata acquisition server412 and processes it in accordance with instructions downloaded from theworkstation402. Such processing may include, for example: Fourier transformation of raw k-space MR data to produce two or three-dimensional images; the application of filters to a reconstructed image; the performance of a backprojection image reconstruction of acquired MR data; the generation of functional MR images; and the calculation of motion or flow images.
Images reconstructed by thedata processing server414 are conveyed back to theworkstation402 where they are stored. Real-time images are stored in a data base memory cache (not shown inFIG. 4), from which they may be output tooperator display412 or adisplay436 that is located near themagnet assembly424 for use by attending physicians. Batch mode images or selected real time images are stored in a host database ondisc storage438. When such images have been reconstructed and transferred to storage, thedata processing server414 notifies thedata store server416 on theworkstation402. Theworkstation402 may be used by an operator to archive the images, produce films, or send the images via a network to other facilities.
The MRgFUS system may include a patient table with anintegrated ultrasound transducer106. Such anultrasound transducer106 is operable to perform the herein described method for providing a non-injurious disruption of the blood-brain barrier. Similar to the previously described FUS system, theultrasound transducer106 may be housed in anenclosure108 that is filled with an acoustically conductive fluid, such as degassed water or a similar acoustically transmitting fluid. Theultrasound transducer106 is preferably connected to apositioning system110 that moves thetransducer106 within theenclosure108, and consequently mechanically adjusts the focal zone of thetransducer106. For example, thepositioning system110 may be configured to move thetransducer106 within theenclosure108 in any one of three orthogonal directions, and to pivot thetransducer106 about a fixed point within theenclosure108 to change the angle of thetransducer106 with respect to a horizontal plane. When the angle of thetransducer106 is altered, the focal distance of the focal zone may be controlled electronically by changing the phase and/or amplitude of the drive signals provided to thetransducer106. These drive signals are provided to the ultrasound transducer by anFUS control system104 that includes drive circuitry in communication with theultrasound transducer106 and a controller that is in communication with thepositioning system110 and drive circuitry.
The top of theenclosure108 may include a flexible membrane that is substantially transparent to ultrasound, such as a Mylar, polyvinyl chloride (“PVC”), or other plastic materials. In addition, a fluid-filled bag (not shown) that can conform easily to the contours of a patient placed on the table may also be provided along the top of the patient table.
The present invention has been described in terms of one or more preferred embodiments, and it should be appreciated that many equivalents, alternatives, variations, and modifications, aside from those expressly stated, are possible and within the scope of the invention.